FR2854022A1 - Microwave device for dehydrating zeolites, has applicator receiving substance e.g. fluid, and three propagation guides symmetrical with respect to ternary symmetry axis of trihedral so that generators are decoupled with each other - Google Patents

Abstract

The device has an applicator to receive a substance e.g. fluid to be processed. Three propagation guides (101-103) propagating microwaves generated by three respective generators are mounted respectively on three plates to form a tri-rectangular trihedral. The guides are arranged in a symmetric manner with respect to ternary symmetry axis of the trihedral such that the generators are decoupled with each other.

Description

MICROWAVE OR RADIO FREQUENCY DEVICE

  INCLUDING THREE DECOUPLED GENERATORS

  The invention relates to a microwave or radio frequency device.

  At present, it is important to design microwave devices achieving very intense and homogeneous electromagnetic field distributions.

  The solution of the multimode resonant cavity is not satisfactory 10 from an industrial point of view because it is applied to small volumes, for example of the order of a liter of product. For large volumes to be treated in industry, it is often necessary to have a total power greater than a few kW, but the design of a homogeneous electromagnetic distribution with a single source then poses a serious problem.

  The invention relates more particularly to a microwave or radio frequency device comprising an applicator intended to receive a product to be treated and several generators supplying the applicator via propagation guides.

  A device of this type is known from European patent application 20 published on July 12, 2000 under the number EP 1018856. Two generators supply the applicator via a magic tee. The homogeneity of the electric field in the applicator is obtained by a combination of the electric field distributions produced by the two generators operating in a decoupled manner with respect to each other, that is to say without debiting one in the other. The decoupling is obtained by the magic tee and by the symmetry of the object to be irradiated with respect to a median plane. However, the supply of this type of device is limited to two generators.

  The object of the invention is to modify a microwave or radio-frequency device of the type mentioned above to increase the total irradiation power of the device while maintaining a homogeneous electromagnetic field distribution in the applicator. .

  To this end, the subject of the invention is a microwave or radio-frequency device comprising an applicator intended to receive a product to be treated and several generators supplying the applicator via propagation guides, characterized in that that three propagation guides propagating the 5 microwaves or radio frequencies generated respectively by three generators are mounted respectively on three plates forming a trirectangular trihedron and are arranged symmetrically with respect to the ternary axis of symmetry of the trihedron so that the generators feed the applicator by being decoupled from each other.

  The decoupling of generators is explained by the theory of electric images. The electromagnetic field produced by a source, located above an indefinite perfectly conducting plane, can be calculated by adding to the electromagnetic field produced by the source, that produced by the symmetrical image of this one compared to the metallic plane.

  The three propagation guides of the device according to the invention are arranged symmetrically on the three faces of the trirectangular trihedron marked OX, OY, OZ to open into the applicator so as to propagate an electric field respectively parallel to the axis OX, parallel to the OY axis and parallel to the OZ axis. The images of the propagation guide arranged in the XOY plane, with respect to the YOZ and ZOX planes, are all located in this same XOY plane with electric fields parallel to OX. In addition, these images emit electric field distributions whose polarization is parallel to OX, that is to say perpendicular to the polarization of the electric field of the distributions emitted by the other two generators. As long as the applicator is empty or occupied by a homogeneous object, the three generators are thus decoupled.

  The decoupling of the three generators allows the applicator to irradiate the object to be treated in a homogeneous manner, with three separate electromagnetic field distributions which add up. The total power supplied by the generators is thus three times that supplied by each of them. It is possible, for example, to irradiate an object with a total power of 2.7 kW using three generators of 900 W each. From an economic point of view, if each generator costs 50 euros, we get 2.7 kW for 150 euros. In addition, the fact of using three low power generators dispenses with the use of circulators which are necessary when using high power generators.

  In this invention each magnetron can be supplied by each of the three phases of the three-phase sector, so that the electrical supply of an applicator remains balanced.

  Other advantages of the invention will appear on reading the description of four embodiments illustrated by the drawings.

  Figure 1 shows schematically a microwave device according to a first embodiment of the invention.

  FIG. 2 is a principle view showing three propagation guides of rectangular section, arranged perpendicular to the faces of the trihedron according to the first embodiment illustrated by FIG. 1.

  FIG. 3 is a principle view showing three propagation guides of rectangular section, arranged parallel to the faces of the trihedron according to a second embodiment.

  FIGS. 4A and 4B schematically show a propagation guide of rectangular section, having slots formed in the long side of the propagation guide.

  FIG. 5 is a principle view showing three propagation guides 20 of a radio-frequency device, in the form of coaxial cables, arranged perpendicular to the faces of the trihedron according to a third embodiment of the invention.

  FIG. 6 is a principle view showing a propagation guide of a radio-frequency device, in the form of a current loop arranged in a plane perpendicular to the faces of the trihedron according to a fourth embodiment of the 'invention.

  FIG. 7 is a principle view showing the three propagation guides of rectangular section illustrated in FIG. 1, mounted removably in rotation about their longitudinal direction of propagation and in translation 30 parallel to the faces of the trihedron on which they are placed.

  FIGS. 8A and 8B schematically show a propagation guide of a device according to FIG. 1, mounted removably in rotation and in translation on one of the plates of the tri-rectangular trihedron. FIG. 9 represents the distribution of the electromagnetic field created by a microwave device 5 according to the first embodiment of the invention, the applicator of circular section being a dehydration reactor.

  FIG. 10 schematically shows a microwave device according to the first embodiment of the invention in which the applicator is a glassmaker oven.

  Referring to Figures 1 and 2, a microwave device according to a first embodiment of the invention comprises an applicator 1 intended to receive an object to be treated 3, for example a liquid, and three generators (not shown) supplying the applicator 1 via three propagation guides 101, 102 and 103. These propagate the microwaves generated respectively by the three generators by being mounted respectively on three plates 71, 72 and 73 forming a trihedral tri -rectangular marked by the axes OX, OY and OZ. The three propagation guides 101, 102 and 103 are arranged symmetrically with respect to the ternary axis of symmetry A of the trihedron. In addition, each propagation guide 101, 102 or 103 extends in a longitudinal direction of propagation L1, L2 or L3 perpendicular to the plate 71, 72 or 73 on which it is mounted.

  In this first embodiment, the three propagation guides 101, 102 and 103 are of rectangular section and mounted respectively on the three plates 71, 72 and 73 so that the short sides 91, 92 and 93 of their rectangular section remain two to two orthogonal. Thus, as illustrated in FIG. 2, the vectors of the electric field, oriented parallel to the short sides 91, 92 and 93 of the rectangular section, are orthogonal to one another. This arrangement allows the three generators to supply the applicator 1 by being decoupled from each other.

  The three propagation guides 101, 102 and 103 open into the applicator 1 through windows 41, 42 and 43 transparent to the microwaves formed at one end of each guide, in correspondence with openings formed in the plates 71, 72 and 73 on which they are mounted. The tri-rectangular trihedron is placed above the applicator 1 along the ternary axis of symmetry A of the trihedron. The product to be treated 3 can be recovered by a lower pipe.

  It should be noted that the presence of the liquid in the applicator shifts the electrical images of the generators with respect to the free surface of the liquid, by an amount related to the permittivity of the liquid. It follows that the three generators remain decoupled even with regard to the waves reflected by the free surface of the liquid.

  As a consequence of the decoupling of the three generators, the distribution of the energy applied to the object to be treated is the sum of the squares of the components of the electric fields generated by each generator. As a result, the contribution of each generator to the total power of the device is as large as possible.

  With reference to FIG. 3, a second embodiment of the invention 15 differs from the previous one in that each propagation guide 201, 202 and 203 extends in a longitudinal direction of propagation ú1, ú2 or 3 parallel to the plate 71, 72 or 73 on which it is mounted. The three propagation guides 201, 202 and 203 are arranged symmetrically with respect to the ternary axis of symmetry A of the trihedron.

  In this second embodiment, the three propagation guides 201, 202 and 203 are also of rectangular section and mounted respectively on the three plates 71, 72 and 73 so that the short sides 91, 92 and 93 of their rectangular section remain two to two orthogonal. This arrangement again allows the three generators to supply the applicator 1 by being decoupled from each other.

  The three propagation guides 201, 202 and 203 open into the applicator through slots 51, 52, and 53 formed in the short side of each propagation guide, in correspondence with openings formed in the plates 71, 72 and 73 on which they are mounted.

  The slots are machined in the short side of the propagation guides to have a length equal to Xg / 4 and to be distant from a short circuit located at the bottom of the guide of (1 + 2n) Ig / 4 o Xg is the length d wave in the rectangular section feed guides. For example, at the frequency of 2450 MHz, Xg is 173 mm for a propagation guide with a section defined by a small side equal to 43 mm and a large side equal to 86 mm. It follows that the distribution of the electromagnetic field is more homogeneous than that which is obtained with the propagation guides with transparent window, like those used in the first embodiment. In addition, the energy density existing in the vicinity of the slots can be adjusted on demand so as not to exceed a critical value and avoid the presence of an arc when it is desired to increase the power of the generators.

  It is planned to form the slots in the long side of the propagation guides of rectangular section. Figure 4A, slots 51A, 52A or 53A are machined in the large side 21A, 22A or 23A of the propagation guides 201-203 in the longitudinal direction L1-L3 of propagation to have a distance between two successive slots equal to? .G / 2 and be distant from a short circuit located at the bottom of the guide of (1 + 2n) Xg / 4 .. Figure 4B, slots 51B, 52B or 53B are machined in the long side 21 B, 22B, 23B propagation guides 201-203 to have a distance between two successive slots equal to 2kg / 2 and to be distant from a short circuit located at the bottom of the guide of n Sg / 2. The angle of the slots with respect to the direction longitudinal propagation of the guides depends on the number of slots 20 machined in a guide. Reference should be made, for example, to the following publication: A.F. Harvey, "Microwave Engineering", Academic Press (1963), pages 634-636 and in particular the references 332 and 457 cited on pages 690 and 694 respectively. With reference to FIG. 5, a third embodiment of the invention differs from the first or from the second mode in that the three propagation guides 251, 302 and 303 are coaxial cables which extend in a direction longitudinal propagation L1, L2 and L3 perpendicular to the plates 71, 72 and 73 and which open into the applicator by one of their stripped ends 81, 82 and 83. The three propagation guides 301, 302 and 303 are arranged symmetrically with respect to the ternary axis of symmetry A of the trihedron. The vectors of the electric field, oriented parallel to the cables 301, 302 are orthogonal to one another. This arrangement again allows the three generators to supply the applicator by being decoupled from each other.

  With reference to FIG. 6, a fourth embodiment of the invention differs from the third mode in that the three propagation guides 401, 402 and 403 are coaxial cables terminated by current loops 411, 412 and 413 The three propagation guides 401, 402 and 403 extend in a longitudinal direction of propagation LI, L2 and L3 perpendicular to the plates 71, 72 and 73 and open into the applicator by a current loop 411, 412 and 5 413 of which a stripped end 421, 422 and 423 is fixed to the corresponding plate of the tri-rectangular trihedron. The three propagation guides 401, 402 and 403 are arranged symmetrically with respect to the ternary axis of symmetry A of the trihedron. The vectors of the magnetic field induced by the current loops are oriented along the axis A perpendicular to the plane of each current loop to remain orthogonal to each other. This arrangement again allows the three generators to supply the applicator by being decoupled from each other.

  Advantageously, for each of the preceding embodiments, the propagation guides 101-103, 201-203 or 301-303 occupy a variable position according to a rotation around their longitudinal direction of propagation and a translation parallel to the plates. 71-73 on which they are mounted while conversing the symmetry with respect to the ternary axis of symmetry A of the tri-rectangular trihedron marked OX, OY, OZ to adjust the decoupling of the generators according to the shape of the object received in applicator 1.

  As illustrated in FIGS. 8A and 8B, a propagation guide 101 is removably mounted by means of a circular flange 801 welded to the propagation guide. The flange 801 comprises twelve smooth holes regularly arranged on a circle to be fixed by bolts to an intermediate plate 501 having twelve corresponding holes. The intermediate plate 25 also comprises four slots 601 receiving bolts to be fixed in turn to the plate 71 of the tri-rectangular trihedron. The twelve holes in the intermediate plate 501 and the flange 801 allow the propagation guide 101 to occupy a variable position in rotation around the propagation direction L1 of the guide, the pitch of rotation being determined by the angular distance 30 between two successive holes. The lights 601 extend parallel to the plate 71 of the tri-rectangular trihedron to allow the propagation guide 101 to occupy a variable position also in translation relative to the plate 71.

  The position of the three guides is thus variable in rotation and in translation, while conversing the position symmetry of the three guides relative to the ternary axis of symmetry (A) of the trihedron. It should be noted that the direction of the lights 601 generally depends on the position of the plates 501 relative to the faces 71-73 of the triangular trihedron.

  It is possible to define a complex reflection coefficient R and a complex transmission coefficient T between the generators supplying the applicator. With reference to FIG. 7, the coefficients R and T are functions of the coordinates xl, yl or y2, z2 or z3, x3 of the center of the section of each guide, respectively 101, 102 or 103, which opens into the applicator , the angle 01 or 02, 03 made by the electric field in the plane of the tri-rectangular trihedron on the face of which the propagation guide, respectively 101, 102 or 103, is arranged and the distance from the object to be treated at the vertex O of the trihedron. The transmission between the propagation guides is canceled by appropriately choosing the three quantities indicated above to restore the decoupling of the three generators. An adapter known per se and disposed in the propagation guide considered also makes it possible to cancel the complex reflection coefficient R seen by each generator.

  The decoupling of the three generators is quantified by measuring the complex coefficient T with a commercial network analyzer. Decoupling is acceptable when the modulus of the transfer coefficient T is less than 0.1 so that only 10% of the power emitted by one generator is received by another. If the transfer coefficient T is greater than 0.1, the generators risk destroying each other and the energy efficiency of the applicator is poor, the efficiency il of each generator being defined by the power delivered to the product compared to the emitted power and worth 25 l = 1 -R2 - 2T2. The reflection coefficient R is also measured using a network analyzer.

  In the first, second or third embodiment, the applicator 1 is of circular or triangular section.

  It should be noted that the distribution of the electromagnetic field 30 in the object to be treated is determined by the fact that an applicator whose section is an equilateral triangle has three fundamental transverse electrical propagation modes which have the same wavelength. cut 2, = 1.5 a. The immediate higher order propagation mode is a TM? C, = (a aJ) / 2 mode and the next TE mode has for 1, = a / 2. The tri-rectangular trihedron, by its symmetry excites the three fundamental modes. As these modes are orthogonal, there is no coupling between the modes created on the one hand and the guides which excite them, on the other hand. The decoupling of the guides remains if the triangular applicator becomes circular.

  Three examples of application of the invention are described below.

  In a first example, the applicator is a gas dehydration reactor comprising a column of zeolites traversed by a wet gas. During the adsorption phase, the water in the gas is adsorbed by the 10 zeolites. When the zeolites have retained an amount of water generally corresponding to 30% of their weight, the column is purged by irradiating it with the microwave device to desorb the water.

  The reactor is cylindrical with a circular section, for example with a diameter equal to 30 cm. With reference to FIG. 1, a microwave device is used according to the first embodiment of the invention: three propagation guides 101, 102 and 103 of rectangular section are mounted respectively on the three faces 71, 72 and 73 of the tri-rectangular OX, OY, OZ trihedron so that the short sides 91, 92 and 93 of their rectangular section remain two to two orthogonal. The trihedron is placed above the reactor by aligning the ternary axis of symmetry A 20 with the central axis of the reactor.

  If the transparent windows of the propagation guides are close to the vertex O of the trihedron, the surface of the adsorbent is irradiated according to curve 1 in FIG. 9. The electromagnetic field has circular symmetry with a maximum in the center of the section and a minimum in the vicinity of the reactor wall. If the transparent windows are moved away from the propagation guides relative to the vertex O of the trihedron, the distribution of the electromagnetic field takes the shape of curve 2. We see that for the diametral plane which passes through a generator, the maximum is shifted towards the opening of the generator considered. The decoupling of the three generators allowing the distributions of the electromagnetic field of each generator to be added as a function of the squares of the modules of the electric fields generates a more uniform total distribution.

  It should be noted that the microwave device is all the more advantageous to use as the energy supplied essentially serves to desorb the water without heating the zeolites, which avoids cooling the column before reusing it for phase d 'adsorption.

  This example shows that by moving away or bringing the three generators closer to the vertex O of the trihedron, the distribution of the radiated electromagnetic field in a section of the applicator is modified, without accepting that the generators flow into each other. It follows that it is thus possible to adjust on demand the overall distribution of the radiated energy in the direction 10 of the axis of ternary symmetry of the trihedron and around it.

  The use of the microwave device according to the invention is not limited to the dehydration of zeolites but is also suitable for any physico-chemical or catalytic operation, such as microwave-stimulated evaporation of a solvent contained in a product or a petrol.

  In a second example, the applicator is a reactor for burning the toxic gaseous components of the air and decontaminating the air by passing the gas through a column filled with a catalyst, for example alumina or silica granules on which metals, for example 0.8% platinum by weight or silicon carbide, have been deposited. The applicator comprises a column having a diameter of 1.5 meters and a height of 2 meters. It is powered by three 10 kW generators, operating continuously at 915 MHz. It should be noted that the air to be treated may circulate only in the center of the column since the vicinity of the wall of the column, corresponding to the hatched parts in FIG. 9, sees an electric field of low intensity.

  In a third example, the applicator is a glass furnace.

  Glass craftsmen often wish to keep several glass bottoms of different colors or different qualities and to dispose of them whenever they want.

  The oven of FIG. 10 comprises a cylindrical crucible 111 of circular section 30, made of refractory alumina silica, pivotally mounted on a metal support 1 10. It can contain several liters of molten glass 113. Heating is obtained by a micro device -waves according to the first embodiment of the invention. The tri-rectangular trihedron is placed above the applicator by aligning the ternary axis of symmetry A with the central axis A of the crucible. The three domestic generators each output a power of 1.2 kW so that the total irradiation power is 3.6 kW. The tri-rectangular OX, OY, OZ trihedron provided with the three propagation guides 101, 102 and 103 rocks around a hinge 114 to allow crucible access to when the glassmaker picks up molten glass.

  It is obvious that the generators are switched off when the oven is open.

  The power emitted by the magnetrons can be finely adjusted so that the operation of the furnace is very economical. It is quickly put into operation, it is possible to change the crucibles which contain different colors and store them separately.

  It should be noted that a microwave device according to the invention, first or second embodiment, operates for example at the frequency of 915 MHz or 2450 MHz. A radio frequency device, third or fourth embodiment, operates for example at the frequency of 13.56 MHz or 27.12 MHz.

Claims (11)

  1. Microwave or radio frequency device comprising an applicator (1,111) intended to receive an object to be treated (3,113) and 5 several generators supplying the applicator via propagation guides, characterized in that three propagation guides (101-103,201-203,301-303,401-403) propagating the microwaves or the radiofrequencies generated respectively by three generators are respectively mounted on three plates (71-73) 10 forming a trihedral triangular (OX, OY, OZ) and are arranged symmetrically with respect to a ternary axis of symmetry (A) of the trihedron so that the generators supply the applicator by being decoupled from each other.   2. Device according to claim 1, characterized in that the three propagation guides (101-103,201-203) are of rectangular section and mounted respectively on the three plates so that the short sides (91-93) of their rectangular section two to two orthogonal remain.   3. Device according to claim 2, characterized in that each propagation guide (101-103) extends in a longitudinal direction of propagation (L1-L3) perpendicular to the plate on which it is mounted.   4. Device according to claim 2, characterized in that each propagation guide (201-203) extends in a longitudinal direction of propagation (l1-ú3) parallel to the plate on which it is mounted.   5. Device according to claim 3 or 4, characterized in that the three propagation guides open into the applicator through windows (41-43) transparent to microwaves formed at one end of each propagation guide.   6. Device according to claim 3 or 4, characterized in that the three propagation guides open into the applicator by slots (5153.51A-51A, 511B-53B) formed in one side (91-93,21A- 23A, 211B23B) of each propagation guide.   7. Device according to claim 1, characterized in that the three propagation guides (301-303) are coaxial cables which extend in a longitudinal direction (L1-L3) of propagation perpendicular to the plates (71-73) and which open into the applicator via a current loop (411-413).   8. Device according to claim 1, characterized in that the three propagation guides (401-403) are coaxial cables which extend in a longitudinal direction (LI-L3) of propagation perpendicular to the plates (71-73) and which open into the applicator 1 0 through one of their stripped ends (81-83) 9. Device according to claim 1, characterized in that the propagation guides occupy a variable position according to a rotation around their longitudinal direction of propagation (L1-L3, 1-e3) and according to a translation parallel to the plates (71-73 ) on which they are mounted while conversing the symmetry with respect to the ternary axis of symmetry (A) of the trihedron (OX, OY, OZ) to adjust the decoupling of the generators according to the shape of the object received ( 3) in the applicator (1).   10. Device according to claim 1, characterized in that the applicator (1) 20 is of circular or triangular section.   11. Device according to claim 1, characterized in that the applicator is a chemical reactor or a glassmaking furnace (111).